DEP0012485MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: August 7, 1954. Advertised on September 27, 1956

GERMAN PATENT OFFICE

The invention relates to a method of manufacture

of trinitrotoluene explosive in free flowing form and a device for performing the process.

When blasting rocks, z. B. in quarries and the like., The explosives must often be rough and uneven Holes are loaded that cannot be loaded well with the usual explosive cartridges. It is also often desirable to load a maximum amount of explosives into the wellbore. If the

ίο Holes do not contain water, the explosives can removed from the pack and poured in loosely. Unfortunately, the holes are mostly damp, especially when they were drilled several days before the demolition.

There are bulk or pourable explosives that are also used in water-containing holes be able. However, they have a low specific gravity, a low bulk density and suffer from the moisture in terms of ignitability and explosiveness. So you have trinitrotoluene (Trotyl) already in flake form and in Granular form of small particle size produced. Although it also flows freely in this form, i.e. trickles, is it is dusty and floats in liquid media, or it clumps so that the column of explosives is interrupted and only low loading densities can be achieved.

It is an object of the present invention to provide a free flowing high explosive Charge density and great sensitivity as well as detonation transmission in liquids. This explosives should be economically feasible from available raw materials and it must be safe to use and be convenient to use.

609 620/115

P 12485 IVa / 78 c

This object is achieved according to the present invention, which provides a method for producing trinitrotoluene explosive concerns in free flowing form, which is characterized by the fact that the Trotyl is in molten State of openings, preferably from about 1.2 to 1.3 mm clear diameter, into a Column of liquid, e.g. B. of water, the temperature at the entry of the Trotyls above the Melting point of the trotyle and in their middle and

ίο lower part a temperature below the freezing point of the Trotyls, and one of the solidified globules from the liquid on mechanical Separating ways.

The invention also relates to a device for the production of trotyl explosive in spherical shape, which is distinguished by a melting container, which is connected to a drip container via a control element that has drip pipes in the ground leading into the top of a tower that is nearby

ao of the drip tubes a heating means, e.g. B. heating coils, above a liquid overflow and below one Liquid inlet and an outlet, e.g. B. has a tube for the liquid-bead mixture, which in a sieve equipped with a sieve bottom

the container leads.

In the drawing is an embodiment of the invention Device illustrated for example.

With ι a funnel-shaped melting container is referred to, which has a steam jacket 2 and a steam coil 3. From the bottom of this melting pot ι leads a pipe via a control valve 5 and a steam-heated pipe 6 into a drip container 7, which has a drip tube 9 in the bottom, which has a clear diameter of approximately 1.2 to i, 3 mm. These drip tubes 9 protrude into the upper part of a cylindrical tower 8, the a steam coil 10 near the drip tube 9, an overflow 12 in the upper part and a water inlet 13 in the lower, preferably conical part and another water inlet 14 has. From the water inlet 13 a pipe 15 leads into the upper part a sieve container 17, into which a water outlet pipe 16 from the middle part of the tower 8 leads. The sieve container 17 has a sieve bottom, and it is arranged in a separating container 18, the bottom has an outlet 19.

To produce trotyl beads according to the invention, the trotyl is brought into the melting container 1 and liquefied therein. It melts in impure state at 76 to 78 ^0, in a pure, crystalline state at 80 to 81 ° and heated in the melting vessel 1 suitably to about 88 °. The melted Trotyl flows through the valve 5 and the steam-heated pipe 6 into the drip container 7, which it fills up to a certain liquid level 4. The valve 5 is expediently set so that a liquid level of 15 to 25 cm of molten Trotyl is maintained in the drip container 7.

The tower 8 is filled with water 11, through the water inlet 14 with a temperature below the solidification point of the Trotyls temperature, ie below about 70 ^0, occurs. It rises in the tower 8 and is heated in the vicinity of the outlet openings of the drip tube 9 by the steam coil to a little above the melting point of the trotyl, so that the trotyl emerges from the drip tube 9 in a molten state and in the form of small spheres into the water filling 4 of the tower 8 is running. Since the trotyl has a greater specific gravity than the water, the trotyl globules sink due to their own gravity, get into the cooler zone of the water column 4, where they solidify, and then sink in the form of solid globules to the bottom, where they move from the Inlet 13 is detected flowing water flow and washed through the pipe 15 into the sieve container 17, on the sieve bottom they collect at 20, while the water from the outlet 19 of the separating container 18 drains.

The beads 20 are now removed from the sieve container and air-dried, so that they cannot freeze together even in cold weather.

In this way, beads are made practical in a simple and safe operation Get a more uniform, perfect spherical shape from Trotyl, which has a diameter of about 1.5 to 5 mm.

The drip tubes 9 are expediently to be arranged at intervals of about 19 mm from one another so that the go Do not stick together emerging, still liquid drops. The. Trotyl emerges from the drip tube 9 in Shape of a drop from the drop tube 9 after reaching the necessary size and Heavy takes over. The trotyl spheres fall down. Because it is perfectly spherical in the hot zone and are quickly quenched in the cold zone, they keep this spherical shape in solid form Condition at.

The trotyl beads according to the invention are distinguished by a fine, dense crystal structure and a hard, smooth, skin-like surface. They are very hard and very resistant to breakage. As a result Due to their uniformity and spherical shape, these explosive spheres run or trickle easily and 10: can be filled in all cavities of dry and moist blast holes.

example 1

From Table 1 is the uniformity and size of trotyl beads produced by the method according to the invention.

table I. 3.36
2.38
2.00 Trotyl
globules
in % Screen size (DIN 1171) 0.2
78.0
21.8
0.0 Residue on sieve 4.76
Passage between sieve 4.67
Passage between sieve 3.36
Passage between sieve 2.38 and
and
and 100.0

These spheres had a diameter of 1: about 3.2 mm, but their diameter, as

620/115

P 12485 IVa / 78 c

thinks to vary between about 1.5 and 5 mm. The diameter depends on the clear diameter of the Drip tube 9, the liquid level in the drip container 7 and the flow rate of the molten Trotyls, the latter being regulated by the liquid level 4. Will this liquid level 4 kept at a constant height in the drip container 7, so beads of uniform size achieved.

If the beads have a diameter of more than 4.7 mm, those emerging from the dropper tube 9 tend Drops due to shrinkage by about 10% when crystallizing to flatten, and the spheres have a cavity on one side. If the globules are smaller than 1.5 mm, they tend to clump together or lumps and form in liquid media, e.g. B. in damp boreholes, incoherent Columns. The very small globules also contain dust and are bad too fiddling.

The trotyl beads produced according to the invention differ from similarly shaped and dimensioned, Trotyl bodies produced by other processes, essentially with regard to the bulk density, Ignitability, explosiveness and detonation transmission in liquid media.

Example 2

The following table 2 shows the surprising differences in the specific gravity of those according to the invention

Trotyl globules can be recognized compared to other trotyl moldings.

Table 2

explosive

Trotyl globules

Trotyl flakes

Molded trotyl cylinders 4.7 mm in length and diameter

Cast Trotyl leaves, broken and sieved through a DIN 4.76 to 3.36 sieve

Example 3

Weight in g cm

0.90 to 1.05 0.70 to 0.85

0.70 to 0.85

0.75 to 0.90

The following tables 3 and 4 show the high specific energy measured after the lead block test. The lead block had a length of 101 mm and a diameter of 38.1 mm and was placed in a water-filled measuring container of the specified diameter and the specified length, which accommodated the test material and the detonator. After the detonation, the bulge of the lead block was measured. The bulge is given in cm ³ . In all cases the primer consisted of a molten 50-50 pentolite charge of 3i, 8mm diameter, which was detonated with a commercially available electric detonator. Pentolite is the nitrate of an alcohol-sugar mixture obtained from formaldehyde and acetaldehyde by condensation.

Table 3 Measuring containers with a diameter of 88.9 mm and a length of 108 mm

Primer 30.0 g

Trotyl globules 45.0 cm ³

Melted trotyl cylinders 4.7 mm in length

and diameter 12.3 cm ³

Trotyl flakes 45.0 cm ³

Melted trotyl leaflets, broken and sieved through a sieve of DIN 4.76 to 3.36 6.1 cm ³

25.0 G 15.0 G 45.0 cm ³ 40.8 cm ³ 12.3 cm ³ 0.0 cm ³ 45, o cm ³ 45, o cm ³

8.2 cm ³

0.0 cm ³

Table 4 Measuring container 28.1 mm in diameter and 228 mm in length

Primer 30.0 g

Trotyl globules 28.7 cm ³

Melted trotyl cylinders from
4.7 mm length and diameter .. 0.0 cm ³

Trotyl flakes 28.7 cm ³

Melted trotyl leaves, broken and passed through a DIN sieve
4.76 to 3.36 sieved 0.0 cm ³

Tables 2 and 3 show that the trotyl beads of the invention have sensitivity and Have explosive power roughly equivalent to that of trotyl flakes, but the melted and broken ones Trotyl cylinders or leaflets of almost the same particle size surpass. The invention For the reasons just mentioned, trotyl spheres are also essential to trotyl flakes

25.0 G 20.0 G I5, o G 10.0 G 28.7 cm ³ 28.7 cm ³ 28.7 cm ³ 28.7 cm ³ 0.0 cm ³ 0.0 cm ³ 0.0 cm ³ 0.0 cm ³ 28.7 cm ³ 28.7 cm ³ 28.7 cm ³ 28.7 cm ³

5.0 g 0.0 cm ³

0.0 cm ³

0.0 cm ³ of 0,0 cm ³ o, o ³ cm ³ cm 0.0 0.0 cm ³

superior because they do not dust and result in a greater loading density. iao

The specific gravity of the trotyl spheres according to the invention should vary between 1.55 and 1.60 for explosive purposes, while the bulk density should be between 0.90 and 1.05. Such globules naturally sink in everyone liquid media which are practically suitable for blasting. The beads can be used for

609 620/11?

P 12485 IVa / 78 c

be used on their own or mixed with other explosives. An example of this is pouring around of nitramone explosive cartridges with the beads according to the invention in boreholes. the Globules are also extremely useful as explosives for oil wells. You will be of the Surface from being poured or poured into shallow oil wells while in deeper or highly viscous Sources containing liquids are useful in

ίο a conventional loading socket on the bottom of the source to be brought. The spheres have good detonation transmission even in columns of only 37 mm in diameter, and their effectiveness is not affected by high fluid pressure.

The trotyl spheres according to the invention also do not suffer from water or other blasting agents Liquids. They can be poured well into cavities filled with air or liquids, flow freely and have a higher specific gravity than

so are all liquids found in blast holes, so that they sink to the ground. Due to its high bulk density, the largest possible amount of Explosives can be filled with the greatest loading density. The beads are also dust-free, safe to use

s5, ignitable and non-toxic using detonators. The invention can be varied widely. An essential feature of the inventive concept is that trotyl droplets in molten State suddenly cooled, so that solid globules are formed. You can get into such globules

also others, e.g. B. Mix in oxygen-supplying substances.

Claims (2)

Pat entans pröc η Ε: 1. Process for the manufacture of trinitrate / toluene explosive in free-flowing form, characterized in that the trinitrotoluene in molten State from openings, preferably from about i, 2 to 1.3 mm clear diameter, into a Column of liquid, e.g. B. of water, which has a temperature at the entry of the trinitrotoluene above the melting point of trinitrotoluene and a temperature in its middle and lower part has below the solidification point of trinitrotoluene, and the solidified globules separates from the liquid by mechanical means. 2. Apparatus for performing the method according to claim 1, characterized by a Melting container (1) which is connected to a drip container (7) via a control element (5), which has drip pipes (9) in the bottom, which lead into the upper end of a tower (8), which is nearby the drip tubes (9) a heating means, e.g. B. heating coils (10), above a liquid overflow (12) and below a liquid inlet (14) and an outlet, e.g. B. a tube (15) for the liquid-bead mixture, which leads into a sieve container (17) equipped with a sieve bottom. 1 sheet of drawings © 609 620/115 9.56